Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation

Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation

The photoinduced structural dynamics of the atomic wire system on the Si(111)-In surface has been studied by ultrafast electron diffraction in reflection geometry. Upon intense fs-laser excitation, this system can be driven in around 1 ps from the insulating (8×2) reconstructed low temperature phas...

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Main Authors: T. Frigge, B. Hafke, T. Witte, B. Krenzer, M. Horn-von Hoegen
Format: Article
Language:English
Published: AIP Publishing LLC and ACA 2018-03-01
Series:Structural Dynamics
Online Access:http://dx.doi.org/10.1063/1.5016619
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spelling doaj-089e0b40d6ea4a37bae46a97f2295c7c2020-11-24T22:25:24ZengAIP Publishing LLC and ACAStructural Dynamics2329-77782018-03-0152025101025101-710.1063/1.5016619001802SDYNon-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitationT. Frigge0B. Hafke1T. Witte2B. Krenzer3M. Horn-von Hoegen4Department of Physics, University of Duisburg-Essen, Lotharstr. 1, 47057 Duisburg, GermanyDepartment of Physics, University of Duisburg-Essen, Lotharstr. 1, 47057 Duisburg, GermanyDepartment of Physics, University of Duisburg-Essen, Lotharstr. 1, 47057 Duisburg, GermanyDepartment of Physics, University of Duisburg-Essen, Lotharstr. 1, 47057 Duisburg, GermanyDepartment of Physics, University of Duisburg-Essen, Lotharstr. 1, 47057 Duisburg, GermanyThe photoinduced structural dynamics of the atomic wire system on the Si(111)-In surface has been studied by ultrafast electron diffraction in reflection geometry. Upon intense fs-laser excitation, this system can be driven in around 1 ps from the insulating (8×2) reconstructed low temperature phase to a metastable metallic (4×1) reconstructed high temperature phase. Subsequent to the structural transition, the surface heats up on a 6 times slower timescale as determined from a transient Debye-Waller analysis of the diffraction spots. From a comparison with the structural response of the high temperature (4×1) phase, we conclude that electron-phonon coupling is responsible for the slow energy transfer from the excited electron system to the lattice. The significant difference in timescales is evidence that the photoinduced structural transition is non-thermally driven.http://dx.doi.org/10.1063/1.5016619
collection DOAJ
language English
format Article
sources DOAJ
author T. Frigge
B. Hafke
T. Witte
B. Krenzer
M. Horn-von Hoegen
spellingShingle T. Frigge
B. Hafke
T. Witte
B. Krenzer
M. Horn-von Hoegen
Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation
Structural Dynamics
author_facet T. Frigge
B. Hafke
T. Witte
B. Krenzer
M. Horn-von Hoegen
author_sort T. Frigge
title Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation
title_short Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation
title_full Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation
title_fullStr Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation
title_full_unstemmed Non-equilibrium lattice dynamics of one-dimensional In chains on Si(111) upon ultrafast optical excitation
title_sort non-equilibrium lattice dynamics of one-dimensional in chains on si(111) upon ultrafast optical excitation
publisher AIP Publishing LLC and ACA
series Structural Dynamics
issn 2329-7778
publishDate 2018-03-01
description The photoinduced structural dynamics of the atomic wire system on the Si(111)-In surface has been studied by ultrafast electron diffraction in reflection geometry. Upon intense fs-laser excitation, this system can be driven in around 1 ps from the insulating (8×2) reconstructed low temperature phase to a metastable metallic (4×1) reconstructed high temperature phase. Subsequent to the structural transition, the surface heats up on a 6 times slower timescale as determined from a transient Debye-Waller analysis of the diffraction spots. From a comparison with the structural response of the high temperature (4×1) phase, we conclude that electron-phonon coupling is responsible for the slow energy transfer from the excited electron system to the lattice. The significant difference in timescales is evidence that the photoinduced structural transition is non-thermally driven.
url http://dx.doi.org/10.1063/1.5016619
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AT bhafke nonequilibriumlatticedynamicsofonedimensionalinchainsonsi111uponultrafastopticalexcitation
AT twitte nonequilibriumlatticedynamicsofonedimensionalinchainsonsi111uponultrafastopticalexcitation
AT bkrenzer nonequilibriumlatticedynamicsofonedimensionalinchainsonsi111uponultrafastopticalexcitation
AT mhornvonhoegen nonequilibriumlatticedynamicsofonedimensionalinchainsonsi111uponultrafastopticalexcitation
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